Sample holder for scanning electron microscopy (sem) and atomic force microscopy (afm)

ABSTRACT

The present invention refers to a two-systems compact specimen holder (SH) easy to use which enables to analyse the same sample by employing either an atomic force microscope (AFM) or a scanning electron microscope (SEM), by preserving the setting reference of the details for both microscopies, so that it satisfies the requirements of size, conductivity, magnetization, tidiness, reference and adaptability. 
     The capacity of preserving the location reference of the details for both microscopies, in the scope of correlational microscopy, results essential to obtain information and images in both fields of microscopy, which can be correlated in order to acquire valuable combined information.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This claims priority to Mexican Patent Application No. MX/a/2015/016988, filed on Dec. 10, 2015, the entire contents of which are fully incorporated herein by reference.

TECHNICAL FIELD

This invention refers to a sample holder (SH), which allows analyzing a single specimen in both, atomic force microscopy (AFM) and scanning electron microscopy (SEM), by keeping the sample-features in the same positioning reference when the sample is inserted in either of the microscopy instruments.

Thus, the present invention is found in the field of devices and supplies used in both SEM and MFA.

BACKGROUND

Sample holders (SH) are devices used to support specimens to be analyzed by SEM and/or AFM and other microscopy techniques. Each of which uses SHs with very particular designs due to their characteristics and specific functionalities [1, 2], such that there is a wide variety of SHs, which not only hold the specimen but also add position, grip, sample size, sample shape, tilting and even confining pressure features. However, none of the existing SH allows studying the same sample in both SEM and AFM, maintaining the sample-features in the same positioning reference. This advantageous feature of keeping the same positioning reference in both microscopy techniques is essential to obtain relevant and complementary information within the correlational microscopy field [3].

Table No. 1 Presents the SHs more closely related to the present invention device features, existing in the market.

TABLE No. 1 SHs for SEM existing in the market, more closely related to the present invention device functionality. Device Device features Observations FIGURE SH for irregular samples such as rock- Designed to hold No. 1 fragments and other abnormal shapes and insert (polymers, metals, etcetera) irregularly (http://www.emsdiasum.com/microscopy/ shaped products/sem/holder.aspx). specimens; not suited for fragile and thin samples. FIGURE Holder for SH tailored for Hitachi ® Too big to be No. 2 SEM, designed for both, flat and inserted in an irregular samples AFM stage. (http://www.ultratecusa.com/sem-stub- holders). FIGURE SH for metallurgic samples although it It cannot be No. 3 may be used to sustain rock fragments, inserted in an polymers and other materials previously AFM. prepared to fit in it. This SH includes a Phillips-type pin underneath and is aluminum made. (http://www.emsdiasum.com/microscopy/ products/sem/holder.aspx). FIGURE SH for SEM dual beam microscopes, It cannot be No. 4 designed to prepare samples on inserted in an transmission electron microscopy AFM stage. (TEM) grids, includes a Phillips-type pin underneath and is aluminum made. (http://www.emsdiasum.com/microscopy/ products/sem/holder.aspx). FIGURE SH for SEM dual beam microscopes, Even without the No. 5 designed to prepare samples on lower pin, it is transmission electron microscopy (TEM) too big to be grids, includes a Phillips-type pin inserted in an underneath and is aluminum made AFM stage. (http://www.emsdiasum.com/microscopy/ products/sem/holder.aspx). FIGURE SH for up to 7 mm thick flat samples The grip method No. 6 used in SEM. It is aluminum made and may damage includes bronze screws and a Phillips- fragile samples type lower pin. and is unable to (http://www.emsdiasum.com/microscopy/ hold small products/sem/holder.aspx). specimens such as AFM specimens, besides is not convenient for AFM-SH and is not magnetic. FIGURE Conventional SH Phillips-type for SEM, It requires No. 7 its dimensions are 12.5 mm, 3.2 mm × double-sided 6.0 mm, aluminum made. tape, and cannot (http://www.agarscientific.com/sem/ be inserted in an specimen-stubs-mounts.html). AFM stage. FIGURE SH Phillips-type for SEM with lower It cannot be No. 8 pin, tailored for acicular specimens inserted in an such as fibers, wires and up to 17.5 AFM stage. mm long sheets and other. because of its (http://www.efjeld.com/P_S-hold.htm). lower pin, and it is too tall for the stage. FIGURE SH designed for thin sheet-like samples The SH cannot No. 9 such as paper, metallic films and wires be inserted in an no larger than 25.4 mm. AFM stage (http://www.efjeld.com/P_S-hold.htm). because of its lower pin.

As it can be seen from Table No. 1, The SEM-designed SHs can be so simple and practical or have a very sophisticated design, providing additional capabilities to support a sample. However, as far as the authors is concerned, none of the existing SHs allows to study the same sample in the same region in both SEM and AFM for the following reasons:

-   -   a) They are not designed to keep the same positioning reference         when changing from SEM to AFM.     -   b) Their physical support can damage fragile samples.     -   c) They are too big to fit into the AFM stage.     -   d) Many of them require the use of electrons-conducting double         sided tape to maintain the specimen in place, which is not         acceptable in AFM imaging since the samples can become         contaminated with the adhesive on the tape and introduce         unexpected damping behavior during both, tapping or continuous         imaging and micromechanical testing in AFM [4].

REFERENCES

-   [1] Bowen, W. R., Hilal, N. Eds. (2009) “Atomic Force Microscopy in     Process Engineering”, Butterworth-Heinemann. Amsterdam, Netherlands. -   [2] Flegler, S. L., Heckerman, J. W., Klomparens, K. L. (1993)     “Scanning and Transmission Electron Microsocpy, an Introduction”,     Oxfrod University Press, New York, EUA. -   [3] Valdré, G. (1999) “Correlative Microscopy and Probing in     Material Science”, Last chapter of the book: Impact of Electron and     Scanning Probe Microscopy on Materials Research. Rickerby, D. G.,     Valdré, G., Valdré, U. Kluwer Academic Publishers. In cooperation     with NATO Scientific Affairs Division. Dordrecht, Netherlands. -   [4] Shaofan L I, Gang Wang. (2008) “Introduction to Micromechanics     and Nanomechanics”, World scientific New Jersey, EUA.

The state of knowledge known by the applicant, represented mainly by the aforementioned devices, technically differs and is exceeded by the present invention, since the present-day knowledge does not report a compact sample holder, easy to use, which facilitates to study the same specimen in the same region in both, AFM and SEM, maintaining the same positioning reference in either microscopy techniques, and satisfying the requirements of size, conductivity, magnetization, cleanliness, referencing and adaptability.

Thus, and objective of the present invention is to provide a SH to analyze the same sample in both SEM and FMA satisfying the requirements of size, conductivity, magnetization, cleanliness, referencing and adaptability.

Another objective of the present invention is to provide a SH to analyze the same sample in both, SEM and AFM, keeping the same positional referencing of any region in the sample.

BRIEF DESCRIPTION OF DRAWING(S)

Note: Numbers in parenthesis ( ), refer to numbers on the figures.

FIGS. 1 to 9 show sample holders (SH) for scanning electron microscopy existing in the market, which are more closely related to the functionality of the present invention.

FIG. 10 shows the SH of the present invention with an attachment block (3), where:

-   -   (1)=SH for AFM or AFM-SH, magnetizable and conductive to         electrons;     -   (2)=SH for SEM or SEM-SH, conductive to electrons; and     -   (3)=attachment block.

FIG. 11 shows the upper view of the present invention SH with attachment block, indicating the measuring scales for referencing in both, AFM-SH and SEM-FH (4).

FIG. 12 shows the front view of SH of the present invention without attachment block and pin.

FIG. 13 shows the side view of SH of the present invention with attachment block, highlighting the Phillips-type support pin (5).

FIG. 14 displays a first example of SH for SEM and AFM of the present invention with vertical flanks and attachment block (3).

FIG. 15 is a display of SH of the present invention with scale-engraved tilted flanks, and captive screw.

FIG. 16 shows the upper view of SH of the present invention with captive screw, highlighting the graduated scales for referencing (4).

FIG. 17 shows the front view of SH of the present invention with captive screw.

FIG. 18 shows the side view of SH of the present invention highlighting the captive screw (6).

FIG. 19 shows a demonstration of the holding action with the captive screw inserted (6) in the SH of the present invention, no support pin is used for atomic force microscopes with a large chamber.

DETAILED DESCRIPTION

The present invention refers to a specimen holder (SH) designed to analyse the same sample in both, an atomic force microscope (AFM) and a scanning electron microscope (SEM), preserving the positioning reference of the sample details in both microscopies, satisfying the requirements of size, conductivity, magnetization, tidiness, referencing and adaptability.

The specimen holder from the present invention is described in the following paragraphs and presented by means of FIGS. 10 to 19, it includes:

-   -   a) A flat sample holder (SH) or AFM-SH(1) also called platen,         that is magnetisable and conductive, with width and thickness         that are appropriate for AFM, having circular shape or any other         shape, where the sample is mounted. This platen (1) has carved         on it, three mutually orthogonal graduated reference axes (4) in         order to facilitate the location of specific details inside the         sample and to insert it inside of a SEM-SH specially designed         for this flat sample holder, as described in the following         paragraphs.     -   b) A SH for SEM or SEM-SH(2) that is electron conductive, it has         tilted flanks with three mutually orthogonal graduated reference         axes carved on them (4), specially designed for the platen (1),         with a box that includes two slots where a graduated platen can         fit in (1). Once the platen is installed (1) on its correct         location, it is fixed with one of the following mechanisms:         -   An attachment block is inserted (3) and fixed with bolts             (FIGS. 10 to 14), and/or         -   It is fixed with a captive screw (6) that prevents the             platen from coming off and from moving (FIGS. 15 to 19).         -   These holding mechanisms prevent from using double-sided             adhesive tape. The SEM-SH from the present invention has             carved, on its upper part, three orthogonal axes (4), with             mutually orthogonal tracking scales in order to pinpoint the             platen axes (1) with respect to those axes.

In addition, the SEM-SH from the present invention may include a removable support pin (5), which can be employed on several other scanning electron microscopes. Some atomic force microscopes can completely accommodate the platen for AFM and the SH for the SEM without the pin, for this reason the present invention includes the option of removable support pin (5). FIG. 13 shows with clarity a Phillips-type removable support pin (5).

The design of the inclined planes and the graduated scales on them in the SEM-SH enables the scales from both AFM-SH and SEM-SH (4) converge to the same plane and thus, both scale systems can be focused at the same time, this eliminates the need of focusing the scale axes of both SEM-SH and AFM-SH independently to track features in either microscope and waste of time and effort.

In this way, the same sample, mounted on the AFM-SH(1) can be analysed on this instrument, with its details being correctly referenced to orthogonal axes, and then can be taken without dismounting the platen (1) to a SEM and be analysed on this new instrument without losing the requirements of conductivity, dimensioning, reference or functionality since it can be inclined, rotated, or translated inside the SEM. This device reduces the fundamental problem of analysing one sample with different techniques included in AFM and SEM by employing the same SH, in such a way that the results from these analyses can now be correlated. 

The following is claimed:
 1. A specimen holder or sample holder (SH) enabling to analyse the same sample by means of atomic force microscopy (AFM) and by means of scanning electron microscopy (SEM), which includes: A flat platen or sample holder (AFM-SH), which is magnetisable and conductive, with appropriate width and thickness for AFM, which has carved on it three mutually orthogonal graduated reference axes (4). A SH for SEM or SEM-SH (2), that is electron conductive, which has carved on it three mutually orthogonal graduated reference axes (4), specially designed for the platen (1), with a box that includes two slots where the AFM-SH slides in (1); mechanisms for holding and securing the platen (1); and a removable support pin (5), to be used in other different scanning electron microscopes.
 2. The specimen holder (SH) from claim 1, where the platen or AFM-SH (1) is circular or has any other shape.
 3. The SEM specimen holder (SEM-SH) from claims 1 and 2, where the platen holding and securing mechanisms (1) include either an attachment block (3) secured with bolts and/or a captive screw (6).
 4. The specimen holder (SH) from vindications 1 to 3, characterized by the fact that it preserves the sample-features location reference when analysed in both microscopies and by the fact that it satisfies the requirements of size, conductivity, magnetization tidiness, reference and adaptability. 